Growth Ahead for Flexible Hybrid Electronics Industry

According to Zion Research, “global demand for the flexible electronics market was valued at $5.13B in 2015 and is expected to generate revenue of $16.5B by 2021, growing at a CAGR of slightly above 21% between 2016 and 2021.” Key elements of the market, in the view of most analysts, include flex displays, sensors, batteries, and memory.

Figure 1: Global flexible electronic market revenue, 2015-2021.

Market research firm Gartner Group says that flexible electronics materials have progressed significantly over the past five years, as have manufacturing techniques, giving rise to increased expectations. The growth of IoT is helping to create many of the new opportunities. Small flexible power sources and sensors can help to drive compact and unique form factors for electronic devices. Health and fitness applications and OLED are markets demonstrating potential for growth as flexible devices and displays. Applications also abound in the automotive, consumer electronics, healthcare, and industrial sectors.

For flexible displays, technology readiness finally meets market demand, as flexible substrates and components become widely available to consumers. IHS estimated in 2016 that the flexible display market would average 27% CAGR over the next several years. In 2001, FlexTech (then the U.S. Display Consortium and now a SEMI Strategic Association Partner) and its members and partners recognized flexibility as one of the next big inflection points for displays and components and the need for collaboration among industry sectors as key to success.

To address that need, the Flexible Display Conference was born with 80 participants and continues this year as 2017FLEX–Accelerating Toward Manufacturing and expects over 600 attendees. The challenges have been considerable in adding flexibility to electronics which have been developed on stable and rigid substrates—attributes which have also constrained them to static and box-like packaging.

Commercializing the introduction of - not just displays - but the many other electronic components in flexible configurations continues as FlexTech’s core focus. The industry will collectively advance flexible electronics at the upcoming 2017FLEX conference and exhibition being held at the Hyatt Regency Hotel and Spa, Monterey, California, June 19-22.

Figure 2: Forecast for the flexible display market.

What is flexible, hybrid electronics?

According to FlexTech, Flexible Hybrid Electronics’ Information Hub, flexible electronics refers to electronic devices built on conformable or stretchable substrates, usually plastic, but also metal foil, paper, and flex glass. They enable a new class of electronics—ones that conform to any shape, but are also bendable, twistable, and/or stretchable. Taking advantage of the ability to conform to organic shapes, electronics can be incorporated into more useful and comfortable consumer and industrial products, capabilities, and features. Combined with rapid advancements in data analytics and artificial intelligence, they can bring digital intelligence to the greater world.

The term "hybrid" refers to designs, which have both printed components and advanced CMOS-based components, allowing the system to process data and activate commands, but also uses the most cost-appropriate componentry for the device. The manufacturing processes bring traditional handling and printing techniques from the paper printing industry: ink placement from heads designed for office printers, chemical formulations from the paint industry, micro- and nano-scale lithography from IC manufacturing, as well as pick-and-placement of die in continuous web processes.

The Return of Flex Displays

Brian Shieh, corporate VP and general manager of the Display Business Group at Applied Materials, says that, “development in the flexible display market is highly anticipated for the next generation of smart phones, tablets/phablets, and other communication devices.”

Companies like E Ink, Yole Développement, FlexEnable, the Holst Center, and SmartKem are deeply involved in this vision and are making progress on flexible electrophoretic displays and OLEDs. E Ink, for example, has created products utilizing flexible, bi-stable, low-power, electrophoretic displays (EPD) in a number of applications, including:

a plastic 32-inch EPD for signage applications

a Sony watch that uses a plastic thin film transistor (TFT) EPD for both the watch face and the watch band

an autonomous 24-inch architectural tile powered by flexible solar cells and no battery

a dress fabricated from flexible EPD media

a 20-inch advanced color ePaper (ACeP) display that shows vivid, full color images produced with a display that incorporates a single un-patterned layer of electrophoretic ink, a single TFT backplane, and no front light

Figure 3: Very thin flexible batteries are being created on a variety of substrates, including flexible ceramic, glass and metal foil.

Mobile Power Initiative

MarketsandMarkets recently estimated that “the wearable technology market is expected to reach $51.6B by 2022 at a CAGR of 15.51% between 2016 and 2022.” If the power sources for these devices are, for example, 10% of the total cost, then the result is a $5B+ market opportunity for flexible batteries and energy-harvesting electronics. The opportunity rests on the fact that new wearable, IOT, and mobile products will not function without power.

FlexTech’s R&D program has created their Power Initiative, designed to create and improve the functionality, printability, and flexibility of power-producing components through contracts with several established and new industry players. ITN is making progress on an all solid-state, thin film lithium rechargeable battery. Custom Electronics is developing and manufacturing a very thin flexible battery. North Carolina State University is involved in energy harvesting, and ETRI in Korea is focusing on supercapacitors.

The manufacturing of flexible and stretchable electronics is an area focusing on maturing a robust process as new methods are being explored and developed by companies such as Flex and Jabil, global EMS providers, in collaboration with NextFlex, America’s Flexible Hybrid Electronics Manufacturing Institute. These organizations are taking on challenges such as water ingress problems, flexibility, stretchability, interconnection challenges, and the lack of acceptable standards for reliability testing. Emerging manufacturing technologies with nano-materials, low temperature soldering, stretchable conductors, printable power, and water resistant coatings are key areas for investigation.

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Growth Ahead for Flexible Hybrid Electronics Industry

Introduction

According toZion Research, “global demand for the flexible electronics market was valued at $5.13B in 2015 and is expected to generate revenue of $16.5B by 2021, growing at a CAGR of slightly above 21% between 2016 and 2021.” Key elements of the market, in the view of most analysts, include flex displays, sensors, batteries, and memory.

Figure 1: Global flexible electronic market revenue, 2015-2021.

Market research firm Gartner Group says that flexible electronics materials have progressed significantly over the past five years, as have manufacturing techniques, giving rise to increased expectations. The growth of IoT is helping to create many of the new opportunities. Small flexible power sources and sensors can help to drive compact and unique form factors for electronic devices. Health and fitness applications and OLED are markets demonstrating potential for growth as flexible devices and displays. Applications also abound in the automotive, consumer electronics, healthcare, and industrial sectors.

For flexible displays, technology readiness finally meets market demand, as flexible substrates and components become widely available to consumers. IHS estimated in 2016 that the flexible display market would average 27% CAGR over the next several years. In 2001, FlexTech (then the U.S. Display Consortium and now a SEMI Strategic Association Partner) and its members and partners recognized flexibility as one of the next big inflection points for displays and components and the need for collaboration among industry sectors as key to success.

To address that need, the Flexible Display Conference was born with 80 participants and continues this year as 2017FLEX–Accelerating Toward Manufacturing and expects over 600 attendees. The challenges have been considerable in adding flexibility to electronics which have been developed on stable and rigid substrates—attributes which have also constrained them to static and box-like packaging.

Commercializing the introduction of - not just displays - but the many other electronic components in flexible configurations continues as FlexTech’s core focus. The industry will collectively advance flexible electronics at the upcoming 2017FLEX conference and exhibition being held at the Hyatt Regency Hotel and Spa, Monterey, California, June 19-22.

Figure 2: Forecast for the flexible display market.

What is flexible, hybrid electronics?

According to FlexTech, Flexible Hybrid Electronics’ Information Hub, flexible electronics refers to electronic devices built on conformable or stretchable substrates, usually plastic, but also metal foil, paper, and flex glass. They enable a new class of electronics—ones that conform to any shape, but are also bendable, twistable, and/or stretchable. Taking advantage of the ability to conform to organic shapes, electronics can be incorporated into more useful and comfortable consumer and industrial products, capabilities, and features. Combined with rapid advancements in data analytics and artificial intelligence, they can bring digital intelligence to the greater world.

The term "hybrid" refers to designs, which have both printed components and advanced CMOS-based components, allowing the system to process data and activate commands, but also uses the most cost-appropriate componentry for the device. The manufacturing processes bring traditional handling and printing techniques from the paper printing industry: ink placement from heads designed for office printers, chemical formulations from the paint industry, micro- and nano-scale lithography from IC manufacturing, as well as pick-and-placement of die in continuous web processes.

The Return of Flex Displays

Brian Shieh, corporate VP and general manager of the Display Business Group at Applied Materials, says that, “development in the flexible display market is highly anticipated for the next generation of smart phones, tablets/phablets, and other communication devices.”

Companies like E Ink, Yole Développement, FlexEnable, the Holst Center, and SmartKem are deeply involved in this vision and are making progress on flexible electrophoretic displays and OLEDs. E Ink, for example, has created products utilizing flexible, bi-stable, low-power, electrophoretic displays (EPD) in a number of applications, including:

a plastic 32-inch EPD for signage applications

a Sony watch that uses a plastic thin film transistor (TFT) EPD for both the watch face and the watch band

an autonomous 24-inch architectural tile powered by flexible solar cells and no battery

a dress fabricated from flexible EPD media

a 20-inch advanced color ePaper (ACeP) display that shows vivid, full color images produced with a display that incorporates a single un-patterned layer of electrophoretic ink, a single TFT backplane, and no front light

Figure 3: Very thin flexible batteries are being created on a variety of substrates, including flexible ceramic, glass and metal foil.

Mobile Power Initiative

MarketsandMarkets recently estimated that “the wearable technology market is expected to reach $51.6B by 2022 at a CAGR of 15.51% between 2016 and 2022.” If the power sources for these devices are, for example, 10% of the total cost, then the result is a $5B+ market opportunity for flexible batteries and energy-harvesting electronics. The opportunity rests on the fact that new wearable, IOT, and mobile products will not function without power.

FlexTech’s R&D program has created their Power Initiative, designed to create and improve the functionality, printability, and flexibility of power-producing components through contracts with several established and new industry players. ITN is making progress on an all solid-state, thin film lithium rechargeable battery. Custom Electronics is developing and manufacturing a very thin flexible battery. North Carolina State University is involved in energy harvesting, and ETRI in Korea is focusing on supercapacitors.

The manufacturing of flexible and stretchable electronics is an area focusing on maturing a robust process as new methods are being explored and developed by companies such as Flex and Jabil, global EMS providers, in collaboration with NextFlex, America’s Flexible Hybrid Electronics Manufacturing Institute. These organizations are taking on challenges such as water ingress problems, flexibility, stretchability, interconnection challenges, and the lack of acceptable standards for reliability testing. Emerging manufacturing technologies with nano-materials, low temperature soldering, stretchable conductors, printable power, and water resistant coatings are key areas for investigation.

MedTech is Changing Medicine

MedTech is a growing market where wireless sensor networks are providing new opportunities for telemedicine, auto-diagnosis, and follow-up treatments. New IoT platforms are integrating sensors to monitor and control the most important body parameters in small, flexible, and portable devices. Some of the companies involved include PARC, who is printing hybrid sensors for health monitoring, and Molex, who is manufacturing sensor systems for biomarker monitoring.

Figure 5: Printed memory provides functionality to devices on the edge of the IoT, including asset tagging and structural health monitoring.

While technology is vital, it is the introduction and application of the technology that moves markets and creates demand. For the past four years, FlexTech’s Nano-Bio Manufacturing Consortium (NBMC) has been in the forefront of human performance monitoring. With multiple NBMC partner R&D projects completed, applications are now being deliberated.

GE Global Research, and a multifaceted team from several other companies and academic institutions, is working on a hydration sensor patch for human performance monitoring funded under FlexTech’s NBMC. Human hydration levels are key parameters in assessing well-being, and the ability to monitor it non-evasively and remotely will mark an important step forward.Libelium, of Zaragoza, Spain, says that these achievements in MedTech applications and products mean an improvement for more than two billion people that cannot access a healthcare system.

Leading universities are actively involved in biosensors. Applications range from wearable biometric monitors (Binghamton University) to optical detection of biomarkers in bodily fluids (University of Cincinnati) to the fusion of fashion with function (Georgia Tech).

Additional FHE Applications

The agriculture sector is also integrating flexible sensors and systems for maximizing crop yields, addressing pest control issues, and other general health and safety issues. TheExperience Co-Creation Partnership of Concord, Massachusetts, most famous for its Internet of Tomato project, has put together 10 starting points for the development of flexible/hybrid sensors for agriculture and food.

Asset monitoring is a growing field, as the U.S. and other countries confront an aging infrastructure of buildings, highways, bridges, and waterways. Additionally, moveable assets—from suitcases to airplanes—benefit from monitoring their location, condition, performance, and other factors. FHE can play a key role in asset monitoring through vibration, temperature, strain, and other sensor technologies. Transmission of the data gathered through RFID, NFC, Bluetooth, or other communication prototypes put the ‘network’ into play. American Semiconductor, Brewer Science, and Thin FilmElectronics are some of the companies exploring this area and incorporating FHE techniques and capabilities into real products.

Results from Research Centers

As an industry consortium, FlexTech maintains active relationships with similar institutes from around the world. This dialogue greatly contributes to shared learning and global networking, as the centers are often the nexus of industry, university, and government collaboration. Among the R&D organizations involved are CEA-LITEN (France), ETRI(So. Korea), Flexible Electronics & Display Center (USA), Fraunhofer Institute (Germany), Holst Center (Netherlands), National Research Council (Canada), PARC(USA), and VTT (Finland). Research topics range from new forms of flexible substrates to TFT and OLED pilot lines to printed health monitoring sensors.

Figure 6: Techniques for shrinking and integrating key components on flexible substrates are being developed under FlexTech R&D program.

Supply Chain Development

The depth of the flexible hybrid circuit industry is not only in manufacturing advancements, but in the progress achieved by materials, equipment, and process suppliers. It includes manufacturing, standards and reliability, substrates, conductors, inspection, encapsulation and coating, nanoparticle inks, direct write, and 3D printing, among others. It involves well-known companies such as Molex, Panasonic,Eastman Chemical, and Northrop Grumman, as well as leading universities and the U.S. Army and U.S. Air Force Research Laboratories.

Developments in this area include Fraunhofer Institute of Germany’s ultrathin glass and biodegradable conductors, direct metallization polyimide from PalPilot, and advancements in printing nano copper from Intrinsiq Materials. ENrG has been working on substrates such as flexible sintered ceramic, while Panasonic has developed insight into electronic materials made with a novel non-silicone stretchable thermosetting polymer. Eastman Chemical is exploring advanced co-polymers as innovative substrates and encapsulants for FHE. Sartomer Americas is continuing its research on energy curable technologies.

Flexible, hybrid electronics have the potential to make our world safer, smarter, healthier, and simpler with advancements in structural health monitoring, smart sensor networks, and medtech applications.

To learn more about the growth in the FHE industry and meet the companies mentioned here and explore their solutions, attend 2017FLEX. View the entire agenda of speakers, exhibitors, and networking opportunities at 2017FLEX.com. To learn more about FlexTech, visit http://www.flextech.org.